CN114687016B - Air suction auxiliary spinning device combined with AI - Google Patents

Abstract

The invention provides an air suction auxiliary type spinning device combined with AI, and relates to the technical field of intelligent spinning equipment. The air suction auxiliary spinning device comprises a cotton sliver feeding mechanism and a trash discharging carding mechanism; the surface of the carding roller is provided with a plurality of air suction holes in an array way, the air suction holes are connected with an air suction device, and an air suction control device is connected with the air suction device and controls the air suction device; the sliver feeding mechanism comprises a sliver guide and a feeding roller, and a sliver self-transmission mechanism is arranged corresponding to the sliver feeding mechanism and comprises an outer circulation traction structure which is connected with an inner circulation traction structure of the sliver can conveying mechanism to form a closed-loop sliver conveying structure so as to convey sliver on the sliver can into a channel of the sliver guide; an impurity detector is arranged corresponding to the sliver guide channel to detect the impurity characteristics of the sliver and control the air suction holes on the carding roller to suck air according to the detection result. The invention realizes artificial intelligent impurity removal based on impurity characteristics, has high impurity removal efficiency, and improves the intellectualization and automation of spinning equipment.

Description

Air suction auxiliary spinning device combined with AI

Technical Field

The invention relates to the technical field of intelligent spinning equipment, in particular to an air suction auxiliary type spinning device combined with AI.

Background

Rotor spinning machines have become the most mature technology in the novel spinning, the application range is the widest, and economic and social effects are great spinning forms. Various impurities such as polypropylene yarns, hair, three yarns and the like often appear in the spinning process, and the appearance of the impurities greatly reduces the quality of products produced by raw materials, so that impurities in cotton sliver are required to be removed in the spinning process.

At present, in an air extraction type rotor spinning machine in the market, there are two modes of carding and impurity stripping: the first is free-falling impurity by the centrifugal force of impurities. The carding roller is generally arranged at a certain included angle alpha (alpha is smaller than 90 degrees) with the vertical surface, the impurity stripping direction and the horizontal surface form an angle alpha, and the impurity removal is called free impurity removal by the comprehensive action of centrifugal force and gravity generated under the drive of high-speed rotation of the carding roller. The mode is longer to the transfer channel of rotor transport fibre for the fibre obtains abundant straightening, and the resultant yarn uniformity is better, and the energy consumption is low. The second is active gettering mode. The carding rollers are vertically arranged, the impurity stripping direction is parallel to the horizontal plane, the impurity removal is carried out by completely depending on high negative pressure suction of air flow, the effective impurity separation can be carried out on various raw materials with larger impurity content, and the application range is wider.

However, the existing impurity removal scheme has the following drawbacks:

1) When the free impurity falling mode is adopted, light impurities with lighter weight such as short velvet and the like are not thrown far in the impurity separation process, are closer to a fiber conveying area, are easy to be sucked back to a carding cavity after being accumulated in a stripping area under the action of fiber conveying negative pressure airflow, generate turning and suck back, lead to the increase of yarn breakage rate and have poor adaptability to regenerated raw materials with more short velvet impurities. When an active gettering mode is adopted, impurities can be stripped along the horizontal plane direction only by requiring higher gettering negative pressure, and the number of the removed impurities is changed due to tiny fluctuation of the gettering negative pressure, so that the variation of thickness knots of the finished yarn is larger; but also has the defects of high equipment energy consumption and easy blockage of the gettering channel. That is, the existing rotor spinning machine carding impurity stripping method cannot achieve the aim of achieving the raw material adaptability, the consistency of the finished yarn quality, low energy consumption and the like.

2) Whether free-falling impurity or active impurity absorption is carried out, all cotton slivers entering the carding cavity are subjected to impurity removal and carding based on the same impurity removal process, and the impurity removal process cannot be adaptively adjusted according to impurity characteristics of cotton sliver raw materials, such as impurity distribution areas, impurity type characteristics and the like. In practice, the impurities are not uniformly distributed on the cotton sliver, some cotton slivers are smaller in impurity, and some cotton slivers are more in impurity; the type of impurities and the connection of impurities to the sliver are not the same, some types of impurities are more tightly connected to the effective fibers, some types of impurities are more loosely connected to the effective fibers, etc. For example, for the impurities tightly connected, a large external force is often required to separate from the cotton sliver, while the impurities loosely connected are easily separated from the cotton sliver, so that no large external force is required, if the indiscriminate impurity removal processes are adopted, the indiscriminate impurity removal processes are indiscriminate, and energy waste is possibly caused, or the impurity removal effect cannot be achieved.

On the other hand, in the conventional spinning production line, the handling of the cans, the joint of the sliver and the feeding of the sliver are often manually transported by a car blocking worker and the connection of various procedures is realized. The sliver can is added with the loaded sliver, the weight is generally over 50kg, and can even reach 80kg, and the labor intensity of workers is increased. Moreover, the spinning workshop has large noise, heavy dust and high temperature, which is not beneficial to the health of workers; along with the improvement of the labor cost, the production cost of spinning mills is improved. Automated can transportation and tampon delivery are thus one direction of automation and intelligence for spinning mills. Although the prior art also provides a technical solution for transferring by an AGV (shuttle) car to reduce the workload of workers. However, the conventional barrel transfer cart is generally only responsible for transferring barrels, and often cannot automatically transfer (feed) the sliver.

In summary, how to provide a feeding carding device capable of not only intelligently discharging impurities according to the impurity type characteristics of cotton sliver, but also automatically conveying sliver cans based on the self characteristics of different impurity types is a technical problem to be solved currently. Further, how to combine raw material adaptability, yarn quality consistency and low energy consumption is also a technical problem to be solved currently.

Disclosure of Invention

The invention aims at: overcomes the defects of the prior art and provides an air suction auxiliary type spinning device combined with AI. According to the air suction auxiliary spinning device provided by the invention, the impurity detector is used for detecting the impurity characteristics of the cotton sliver, air suction is carried out on the carding roller through the air suction holes according to the detection result, so that negative pressure is formed on the surface of the carding roller to generate auxiliary adsorption force, and meanwhile, impurities mixed in the cotton sliver are sucked through the air suction holes, so that self-adaptive impurity suction based on the impurity characteristics of the cotton sliver is realized, and the impurity removal effect and the energy saving requirement are considered; meanwhile, the sliver self-transmission mechanism and the sliver can conveying mechanism are arranged corresponding to the sliver feeding mechanism, so that sliver can conveying and sliver can automatic feeding are realized, and automation, serialization and intellectualization of spinning equipment are improved.

In order to achieve the above object, the present invention provides the following technical solutions:

an air suction auxiliary spinning device combined with AI is used in a rotor spinning machine and comprises a cotton sliver feeding mechanism and a trash discharging carding mechanism;

the impurity removing and carding mechanism comprises a carding cavity provided with a carding roller, the carding cavity is communicated with the cotton sliver feeding mechanism and the fiber conveying channel, and an air supplementing channel and an impurity removing area of the carding cavity are arranged below the corresponding carding cavity; the surface of the carding roller is provided with a plurality of air suction holes in an array manner, the air suction holes are connected with an air suction device, and the air suction control device is connected with the air suction device and controls the air suction device;

The cotton sliver feeding mechanism comprises a sliver guide and a feeding roller, an outlet of a channel of the sliver guide is connected with the feeding roller, and cotton slivers are conveyed into the carding mechanism for carding under the rotation of the feeding roller; the sliver conveying mechanism is used for conveying sliver on the sliver can to the channel of the sliver guide device;

the device comprises a sliver guide channel, an air suction control device, an impurity detector, an air suction control device, a sliver guide channel and a sliver guide channel, wherein the impurity detector is arranged corresponding to the sliver guide channel and connected with the air suction control device, impurity information of the sliver in the sliver guide channel is detected through the impurity detector, a detection result is sent to the air suction control device, and the impurity information comprises area information of impurities;

the pumping control device is configured to: when cotton sliver fed into the carding cavity is carded by the carding roller, the air suction holes corresponding to the area where the impurities are positioned on the carding roller are controlled according to the detection result to suck air to form negative pressure on the surface of the carding roller so as to generate auxiliary adsorption force, and meanwhile, the impurities mixed in the cotton sliver are sucked away through the air suction holes.

Further, the carding roller comprises an inner cylinder fixedly arranged, an outer cylinder coaxially and rotatably arranged with the inner cylinder, and an adsorption cavity arranged between the outer cylinder and the inner cylinder;

the surface of the outer cylinder is provided with carding wires and air suction holes in an array manner, and impurities mixed in the inner side of the cotton sliver are sucked into the adsorption cavity through the air suction holes when air is pumped;

the inner cylinder is a hollow cavity, the hollow cavity is communicated with the air extractor, a vent hole is formed in the wall of the inner cylinder to communicate the adsorption cavity with the hollow cavity of the inner cylinder, and when air is extracted, air on the surface of the carding roller enters the adsorption cavity through the air suction hole and then enters the hollow cavity through the vent hole and is extracted by the air extractor.

Further, one end or two ends of the hollow cavity of the inner cylinder are communicated with an air extractor, and an adhesion layer is arranged in the adsorption cavity to adhere impurities entering the adsorption cavity.

Further, the sliver guide comprises a feeding horn and a feeding plate, the feeding plate is positioned below the feeding roller, and the feeding roller and the feeding plate are commonly held to form holding force for sliver; the front end of the feeding plate forms a feeding jaw, a spring is arranged under the feeding plate, the pressure of the feeding jaw is from the spring, and the pressure of the feeding jaw is adjusted by adjusting the compression amount of the spring.

Further, the impurity detector comprises a camera, an image recognition unit and an impurity evaluation unit, wherein the camera is positioned at the inner side of the feeding horn; the camera is used for shooting image data of cotton sliver in the feeding horn and transmitting the image data to the image recognition unit, and the image recognition unit is used for carrying out recognition analysis on the image data of the cotton sliver to acquire impurity distribution information and impurity type information in the cotton sliver, and then sending the impurity distribution information and the impurity type information to the impurity evaluation unit; the impurity evaluation unit is used for evaluating the impurity grade of the sliver and marking the important impurity area according to the impurity distribution information and the impurity type information, and sending the evaluation grade and the marking area information to the air extraction control device;

the air suction control device can control the air suction holes of the corresponding area on the carding roller to suck air according to the information of the marked area, and select the air suction quantity corresponding to the evaluation grade according to the evaluation grade.

Further, the barrel conveying mechanism comprises a shifting robot with a base, a barrel placing area and an internal circulation traction structure are arranged on the base, a sliver limit structure is arranged on the internal circulation traction structure to fix sliver heads on the barrel, and the sliver limit structure can release the fixation of the sliver heads;

The joint structure is arranged corresponding to the external circulation traction structure and/or the internal circulation traction structure, after the barrel is transported to the position of the external circulation traction structure through the shifting robot, the connector structure is controlled to connect the external circulation traction structure and the internal circulation traction structure to form a closed-loop cotton sliver conveying structure, and cotton slivers on the sliver cans are conveyed into a channel of the sliver guide through the cotton sliver conveying structure; and when the sliver head enters the front end of the sliver guide, the sliver limiting structure is released from fixing the sliver head, and the sliver is conveyed to the impurity removing carding mechanism under the rotation of the feeding roller.

Further, a sliver detecting structure is arranged corresponding to the sliver guide, the sliver detecting structure detects whether sliver exists in a preset area in a sliver guide channel, and a can changing instruction is sent when sliver does not exist;

according to the cylinder changing instruction, the joint structure is controlled to release the connection between the external circulation traction structure and the internal circulation traction structure, so that the cylinder conveying mechanism can be separated from the cotton sliver self-transmission mechanism, and the empty cylinder is conveyed away through the shifting robot.

Further, the cotton sliver limiting structure is a clamping structure, the clamping structure comprises a clamp and a clamping canceling structure, and the clamping canceling structure can drive the clamp to loosen to cancel clamping; a position detection structure is arranged corresponding to the clamp, position information of the clamp is obtained through the position detection structure, whether the clamp reaches the front end of the bar guide is judged, and a clamping releasing instruction is sent out when the clamp reaches the front end of the bar guide; and according to the clamping-releasing instruction, controlling the clamping-releasing structure to drive the clamp to release so as to release the fixation of the sliver head.

Further, the impurity stripping area corresponding to the carding cavity impurity discharging area is provided with an impurity stripping surface which is arranged in a downward inclined mode, the impurity stripping surface is provided with an impurity sucking opening, a downward inclined impurity stripping channel is formed at the lower portion of the carding roller through the impurity stripping surface, the impurity stripping channel comprises an effective fiber area, a rolling back suction area and a free impurity falling area from top to bottom, impurities in the rolling back suction area are sucked into the impurity sucking channel through the impurity sucking opening to be discharged, and impurities in the free impurity falling area fall into the impurity discharging area to be discharged.

Further, the impurity stripping surface and the horizontal surface are arranged obliquely downwards at an angle of 60-70 degrees.

Compared with the prior art, the invention has the following advantages and positive effects by taking the technical scheme as an example:

on the one hand, the auxiliary type spinning device breathes in detects silver impurity characteristics through the impurity detector to bleed through the suction hole on opening the comb roller according to the detection result and form negative pressure on opening the comb roller surface in order to produce auxiliary adsorption affinity, the impurity that is mingled with in the silver is simultaneously sucked away through the suction hole, has realized the self-adaptation that is based on silver impurity characteristics and has inhaled miscellaneous effect of row and energy-conserving demand of having taken into account.

On the other hand, the sliver self-transmission mechanism and the sliver can conveying mechanism are arranged corresponding to the sliver feeding mechanism, so that sliver can conveying and sliver can sliver automatic feeding are realized, automation, serialization and intellectualization of spinning equipment are improved, artificial intelligence impurity removal based on sliver impurity types is realized, and impurity removal effect and energy saving requirement of light impurities are considered.

On the other hand, the free-falling impurity and the accurate impurity absorption are organically combined, and the method has the characteristics of wide raw material adaptability, good consistency of finished yarn quality and low energy consumption.

Drawings

Fig. 1 is a schematic structural view of a spinning device according to an embodiment of the present invention.

Fig. 2 is a schematic structural diagram of a carding roller with air suction holes according to an embodiment of the present invention.

Fig. 3 is a schematic structural view of a cotton sliver feeding mechanism according to an embodiment of the present invention.

Fig. 4 is a schematic structural diagram of a displacement robot for carrying cans according to an embodiment of the present invention.

Fig. 5 is a schematic diagram of a connection structure between a sliver self-driving mechanism and a can transporting mechanism according to an embodiment of the present invention.

Fig. 6 is a schematic structural diagram of a double-row impurity carding mechanism according to an embodiment of the present invention.

Fig. 7 is a schematic diagram of a partition of an impurity stripping channel according to an embodiment of the present invention.

Reference numerals illustrate:

a spinning device 100;

a housing 110;

carding roller 120, fiber transfer area 121, outer cylinder 122, suction hole 123, inner cylinder 124, vent 125, and transmission pipeline 126; an air extracting device 90, an air extracting control device 91;

a sliver feeding mechanism 130, a sliver guide 131, a feeding horn 131-1, a feeding plate 131-2, and a feeding roller 132;

a fiber delivery channel 140;

A make-up air passage 150;

a carding cavity impurity discharging area 160, an impurity stripping channel 161, an effective fiber area 161a, a turnover back suction area 161b and a free impurity falling area 161c;

an impurity peeling surface 170, a gettering port 171, a gettering channel 172, a suction pipe 173, and a blowing means 174;

an outer circulation traction structure 180;

a displacement robot 190, a base 191, a displacement structure 192, a barrel placement area 193, an internal circulation traction structure 194, a joint structure 195, a main body support 196 and a cotton sliver limiting structure 197;

barrel 300, tampon barrel 301.

Detailed Description

The air suction assisted spinning device incorporating AI according to the present invention will be described in further detail with reference to the accompanying drawings and specific examples. It should be noted that the technical features or combinations of technical features described in the following embodiments should not be regarded as being isolated, and they may be combined with each other to achieve a better technical effect. In the drawings of the embodiments described below, like reference numerals appearing in the various drawings represent like features or components and are applicable to the various embodiments. Thus, once an item is defined in one drawing, no further discussion thereof is required in subsequent drawings.

It should be noted that the structures, proportions, sizes, etc. shown in the drawings are merely used in conjunction with the disclosure of the present specification, and are not intended to limit the applicable scope of the present invention, but rather to limit the scope of the present invention. The scope of the preferred embodiments of the present invention includes additional implementations in which functions may be performed out of the order described or discussed, including in a substantially simultaneous manner or in an order that is reverse, depending on the function involved, as would be understood by those of skill in the art to which embodiments of the present invention pertain.

Examples

Referring to fig. 1, an AI-combined air-aspiration-assisted spinning device 100 according to the present invention is used in a rotor spinning machine, and includes a sliver feeding mechanism and a trash removal carding mechanism.

The impurity removing carding mechanism comprises a shell 110 provided with a carding cavity, a carding roller 120 is arranged in the carding cavity, and a cotton sliver feeding mechanism 130 and a fiber conveying channel 140 which are respectively communicated with the carding cavity are arranged on the shell 110. The left side of the carding roller 120 is provided with a fiber transfer area 121 for transferring the carded sliver. The fiber transfer area 121 is arranged below the fiber conveying channel 140, and cotton sliver passes through the fiber transfer area 121 after carding and is conveyed to the rotating cup through the fiber conveying channel 140.

During spinning, cotton sliver is fed into the carding cavity through the cotton sliver feeding mechanism 130 for carding, and carded fibers enter the rotor through the fiber conveying channel 140 and then come out of the coagulation tank, are drawn into the false twisting disc and are made into yarns.

Corresponding to the air supplementing channel 150 and the carding cavity impurity removing region 160 which are arranged below the carding cavity.

The carding cavity is used for supplementing air through the air supplementing channel 150, and the air supplementing direction corresponds to the lower part of the carding roller 120.

Below the carding chamber is a carding chamber impurity removal region 160. Specifically, an impurity peeling surface 170 is provided on the housing 110 corresponding to the carding chamber impurity discharging region 160, and a downward inclined impurity peeling passage may be formed at the lower portion of the carding roller 120 by the impurity peeling surface 170. When carding cotton sliver by the carding roller, the carding cavity is supplemented with air through the air supplementing channel 150, and impurities or partial impurities fall into the impurity discharging belt to be discharged along the impurity stripping surface 170 of the impurity discharging area 160 of the carding cavity under the action of self gravity.

The surface of the carding roller 120 is provided with a plurality of air suction holes 123 in an array manner, and the air suction holes 123 are connected with the air suction device 90. The air extraction device 90 is preferably an air pump. The connection includes directly connecting the suction holes 123 with the suction devices 90, such as, for example, disposing a mini-suction device 90 corresponding to each suction hole 123; indirectly connecting the suction holes 123 to the suction device 90 via connecting lines, control structures, or other desired connections, such as by way of example, combining multiple suction holes 123 into a main line via various sub-lines, and then connecting the main line to the suction device 90.

When cotton sliver is combed by the carding roller 120 rotating at a high speed, the air extractor can be started, the air extractor 90 is used for extracting air from the air suction holes 123, the ambient air on the surface of the carding roller is extracted to form negative pressure, the negative pressure generates auxiliary adsorption force on the cotton sliver on the surface of the carding roller, and meanwhile, impurities mixed in the inner side of the cotton sliver are sucked through the air suction holes 123. The cotton sliver inner side refers to one side of the cotton sliver close to the carding roller, and as the cotton sliver entering the carding roller for carding has a certain thickness, one side close to the carding roller is called an inner side in the invention, and one side far from the carding roller is called an outer side in the invention. After the mode is adopted, impurities which are mixed inside the cotton sliver and are not separated from the effective fibers are removed through the air suction holes while impurities are removed through precise impurity absorption and free impurity falling in the impurity removing area of the carding cavity (the impurities are mainly impurities separated from the effective fibers), so that the impurity removing efficiency is remarkably improved.

In a preferred embodiment, referring to fig. 2, the carding roll 120 is a double-layer cylinder structure, and includes an inner cylinder 124 fixedly disposed, an outer cylinder 122 rotatably disposed coaxially with the inner cylinder 124, and an adsorption cavity disposed between the outer cylinder 122 and the inner cylinder 124.

The surface of the outer cylinder 122 is provided with carding wires (not shown) and air suction holes 123 in an array. During air suction, impurities trapped inside the sliver can be sucked into the adsorption cavity through the suction hole 123.

The inner cylinder 124 is a hollow cavity, and the hollow cavity can be communicated with the air extractor 90 through a transmission pipeline 126. The wall of the inner cylinder 124 is provided with a vent hole 125 to communicate the adsorption cavity with the hollow cavity of the inner cylinder. During air extraction, air on the outer surface of the carding roller enters the adsorption cavity through the air suction holes 123, then enters the hollow cavity through the air holes 125 on the inner cylinder 124, and is extracted by the air extraction device 90 through the transmission pipeline 126.

The air extraction device 90 may be disposed at one or both ends of the hollow cavity of the inner barrel 124 and in communication with the hollow cavity. In order to leave impurities in the adsorption chamber, an adhesion layer may be further provided in the adsorption chamber to adhere impurities entering the adsorption chamber. The adhesive layer includes, but is not limited to, one or more of barb adhesion, adhesive/sheet adhesion, electromagnetic adhesion. Preferably, the adhesion layer is detachably installed in the adsorption cavity, and when impurities cannot adhere to the adhesion layer, the adhesion layer can be detached to be replaced by a new adhesion layer.

The air extraction control device 91 can be further arranged corresponding to the air extraction device 90 to adjust the opening and closing of the air extraction device 90 and the air extraction path (a valve can be arranged according to the requirement to perform multi-pipeline adjustment), the air extraction flow rate and the like according to the requirement. Preferably, the air extraction control device 91 includes a controller disposed on an air pump or an air transmission line, and the air pump or the air transmission line can act on the corresponding air suction hole under the control of the controller.

It should be noted that, although only the air suction holes arranged in a matrix manner are illustrated in fig. 2, those skilled in the art should understand that the air suction holes 123 may be arranged on the carding roller 120 in various array forms such as a matrix array, a quincuncial array, a hexagonal array, etc., and the specific shape of the array should not be taken as a limitation of the present invention.

Referring to fig. 3, the cotton sliver feeding mechanism 130 includes a sliver guide 131 and a feeding roller 132, an outlet of a channel of the sliver guide 131 is connected to the feeding roller 132, and cotton slivers are conveyed into the carding mechanism for carding under the rotation of the feeding roller 132.

Preferably, the bar guide 131 includes a feed horn 131-1 and a feed plate 131-2.

The feeding horn 131-1 may be made of plastic or bakelite, and the cross section of the passage gradually contracts from the inlet to the outlet to be flat, and the cross section of the cotton sliver correspondingly changes when passing through the feeding horn. The inner wall of the feeding horn is smooth, so that friction resistance of the horn mouth to the cotton sliver is reduced, and accidental drafting is avoided, so that uniformity of the cotton sliver is damaged.

The feeding plate 131-2 is located below the feeding roller 132, and the feeding roller and the feeding plate are held together to form a holding force for the cotton sliver. The front end of the feeding plate forms a feeding jaw, a spring is arranged under the feeding plate, the pressure of the feeding jaw is from the spring, and the pressure of the feeding jaw is adjusted by adjusting the compression amount of the spring.

The feeding roller 132 is preferably a grooved roller, which is held together with the feeding plate 131-2, and feeds the sliver to the carding roller 120 for carding by positive rotation of the feeding roller 132. To prevent the sliver from spreading toward both ends of the carding roller when carding, the front end of the feeding plate 131-2 is designed to be concave, thereby limiting the width of the sliver.

In this embodiment, an impurity detector is provided corresponding to the sliver guide channel, the impurity detector is connected with the air extraction control device 91, the impurity information of the sliver in the sliver guide channel is detected by the impurity detector, and the detection result is sent to the air extraction control device 91, and the impurity information includes the area information of the impurity.

The air extraction control device 91 is connected to the air extraction device 90 and controls the air extraction device 90. During spinning, the impurity detector detects impurity information of the sliver in the sliver feeding mechanism 130 and sends the detection result to the air extraction control device 91, and the air extraction control device 91 can control the air extraction area and/or the air extraction amount of the air suction hole 123 on the carding roller 120 according to the detection result.

In this manner, the suction holes 123 on the surface of the carding roller 120 may be divided into a plurality of areas, and the suction holes 123 in one area are grouped, and the suction holes 123 in one group are controlled by one independent controller. Further, a pressure sensor may be disposed in the air suction hole 123, and the air pressure of the air suction hole 123 is monitored by the pressure sensor and the air pressure detection value may be fed back to the controller, and the controller in the corresponding area may adjust the air suction amount and/or the total air suction amount in unit time according to the air pressure.

By way of example and not limitation, the suction holes 123 on the carding roll 120 are divided into n zones (n is an integer of 2 or more), including zone 1 suction holes, zone 2 suction holes, zone n suction holes, the suction holes of each zone being controlled in suction by one independent controller, all of which are connected to the main control portion of the suction control device 91. The main control unit of the air extraction control device 91 can evaluate the target area corresponding to the sliver after the sliver enters the carding roller 120 according to the sliver impurity information detected by the impurity detector, and then control the air suction hole corresponding to the target area to perform air extraction. As an example, for example, 9 suction holes in a circular frame with a broken line in fig. 2 are suction holes in area 1, and when it is estimated that the impurity in the sliver is located in the area, the main control part of the suction control device 191 sends a suction instruction to the controller of the suction holes in area 1, and the air pump corresponding to the suction holes in area 1 is started or the air transmission pipeline is opened, so that suction starts, and the impurity mixed in the inner side of the sliver can be sucked into the adsorption cavity through the suction holes 123.

Preferably, the impurity detector may include a camera, an image recognition unit, and an impurity evaluation unit.

The camera is located the feeding loudspeaker inboard, and the camera is arranged in shooting feeding loudspeaker middle silver image data and transmits to image recognition unit.

The image recognition unit is used for carrying out recognition analysis on the cotton sliver image data to obtain impurity distribution information and impurity type information in the cotton sliver, and then sending the impurity distribution information and the impurity type information to the impurity evaluation unit.

The impurity evaluation unit is used for evaluating the sliver impurity grade and marking the impurity key area according to the impurity distribution information and the impurity type information, and sending the evaluation grade and the marking area information to the air extraction control device.

The air suction control device can control the air suction holes of the corresponding area on the carding roller to suck air according to the information of the marked area, and select the air suction quantity corresponding to the evaluation grade according to the evaluation grade. By way of example and not limitation, the impurity class of the sliver is 3, i.e. the impurity class of the sliver is easy to separate, the impurity class is common, and the impurity class is difficult to separate, wherein the extraction quantity (which can be the extraction quantity in unit time when the extraction quantity also starts) corresponding to the impurity class is minimum, the extraction quantity corresponding to the impurity class is central, and the extraction quantity corresponding to the impurity class is maximum.

In this embodiment, a sliver self-driving mechanism is further disposed corresponding to the sliver feeding mechanism 130. The tampon self-transfer mechanism includes an outer circulation traction structure 180 disposed in correspondence with the guide channel. The outer circulation traction structure 180 is used for being connected with the inner circulation traction structure of the barrel conveying mechanism to form a closed loop of cotton sliver conveying structure, and cotton slivers on the barrel are conveyed into the channel of the sliver guide through the cotton sliver conveying structure.

The barrel transport mechanism is used to transport the barrel 300 and to connect the tampons on the barrel 300 to the outer circulation traction structure 180. Specifically, the can transport mechanism may include a displacement robot 190 having a base on which a can placement area and an internal circulation traction structure are disposed. The cans 300 are loaded through the can placement zones. The barrel 300 serves as a storage container for tampons, and the tampons on the barrel may be two-pass drawing, one-pass drawing, or raw as desired.

The cotton sliver limiting structure is arranged on the internal circulation traction structure to fix cotton sliver heads on the sliver cans, and the cotton sliver limiting structure can be used for releasing the fixation of the cotton sliver heads.

The sliver conveying device comprises a sliver guiding device, wherein a sliver guiding device is arranged on the sliver guiding device, and a sliver guiding device is arranged on the sliver guiding device. And when the sliver head enters the front end of the sliver guide, the sliver limiting structure is released from fixing the sliver head, and the sliver is conveyed to the impurity removing carding mechanism under the rotation of the feeding roller.

Preferably, the corresponding sliver guide may further be provided with a sliver detecting structure, and the sliver detecting structure detects whether a sliver exists in a preset area in the sliver guide channel, and sends a can changing instruction when the sliver does not exist. According to the cylinder changing instruction, the joint structure is controlled to release the connection between the external circulation traction structure and the internal circulation traction structure, so that the cylinder conveying mechanism can be separated from the cotton sliver self-transmission mechanism, and the empty cylinder is conveyed away through the shifting robot.

In this embodiment, the outer circulation traction structure and the inner circulation traction structure may adopt a transmission chain or a transmission belt.

Preferably, the outer circulation traction structure and the inner circulation traction structure are made of isomorphic transmission chains or transmission belts. The outer circulation traction structure may include a plurality of conveyor chain units or conveyor belt units connected end to end, and the inner circulation traction structure also includes a plurality of conveyor chain units or conveyor belt units connected end to end, the joint structure including an upper joint member and a lower joint member. When the outer circulation traction structure is connected with the inner circulation traction structure, the upper end of the inner circulation traction structure is connected with the upper end of the outer circulation traction structure through the upper joint piece, and the lower end of the inner circulation traction structure is connected with the lower end of the outer circulation traction structure through the lower joint piece, so that a closed-loop cotton sliver transmission chain or transmission belt is formed.

The sliver transfer chain or belt is preferably arranged in correspondence of the guide channels by a plurality of guide wheels. At least one of the guide wheels is a driving wheel, the rest guide wheels are driven wheels, and the driving wheel rotates under the drive of a rotary driving structure, so that the driven wheels are driven to rotate to form a closed-loop cotton sliver transmission chain or belt.

Preferably, 3 guide wheels are arranged corresponding to the guide channels to form a triangular or approximately triangular sliver conveying chain or conveying belt. As shown in fig. 1, sliver conveying guide wheels are arranged below the corresponding sliver guide channels, upper guide wheels are arranged at the upper joint positions corresponding to the inner circulation traction structure and the outer circulation traction structure, and lower guide wheels are arranged at the lower joint positions corresponding to the inner circulation traction structure and the outer circulation traction structure. The cotton sliver conveying guide wheel can be set to be a driving wheel, and a selective driving structure is arranged corresponding to the driving wheel; the rest guide wheels are driven wheels and can rotate under the transmission action of a chain or a transmission belt. When cotton sliver is fed and conveyed, the driving wheel rotates under the driving of the rotary driving structure, so that the driven wheel is driven to rotate to form a closed loop cotton sliver conveying chain or conveying belt.

Referring to fig. 4, a preferred structure of the displacement robot 190 is illustrated. The displacement robot 190 comprises a base 191, a displacement structure 192 is arranged at the lower part of the base 191, a barrel placement area 193 is arranged at the upper part of the base 191, an inner circulation traction structure 194 is arranged through a main body support 196, joint structures 195 are respectively arranged at the upper end and the lower end of the inner circulation traction structure 194, and a cotton sliver limiting structure 197 is arranged at the upper part of the inner circulation traction structure 194.

A controller of the displacement robot may be installed in the housing of the base 191, and information transmission and reception, information processing, and operation control may be performed by the controller.

The displacement structure 192 is used to effect a positional movement of the robot. The displacement robot 190 may or may not move on a predetermined track, and the displacement structure matches the shape of the track when the track movement is adopted.

In this embodiment, preferably, trackless movement is used, and displacement mechanism 192 may be a fixed caster, a movable caster, or a track. At this time, a related map such as a factory map of a factory where the spinning equipment is located may be stored in a memory of the controller or an associated server; after the shift robot 190 receives the conveyance command, the controller determines a travel path based on the factory map, and controls the shift structure to start, and conveys the cans.

The can placement area 193 is used to load cans, and the configuration of the can placement area 193 when loading cans 300 is illustrated in fig. 4.

The inner circulation traction structure 194 is adapted to be coupled to the outer circulation traction structure 180. Specifically, the upper and lower ends of the inner circulation traction structure 194 are respectively provided with a joint structure 195, and the inner circulation traction structure 194 is connected with the outer circulation traction structure 180 through the joint structure 195.

The connector structure 195 is used for detachably connecting the inner circulation traction structure 194 and the outer circulation traction structure 180, so that the inner circulation traction structure 194 and the outer circulation traction structure 180 can be connected into a closed-loop transmission structure for sliver feeding and conveying when needed, and can be separated when needed so as to replace an empty barrel. In this embodiment, the fitting structure 195 preferably employs a snap connection, an adsorption connection, and/or a clip connection.

The clamping connection piece preferably adopts a snap fastener with a circular groove.

The adsorption connection piece preferably adopts a magnetic adsorption connection piece, and the detachable connection of the inner circulation traction structure 194 and the outer circulation traction structure 180 is realized by the principle of opposite magnetic pole attraction, preferably adopts an electromagnet structure.

The clip connector preferably adopts a clip. The clip comprises two cross arms and a vertical arm connecting the two cross arms, wherein the two cross arms are respectively inserted into the open holes at the tail ends of the inner circulation traction structure 194 and the outer circulation traction structure 180 and limited by the limiting structure in the open holes, thereby realizing the connection between the tail ends of the inner circulation traction structure 194 and the outer circulation traction structure 180. The limiting structure can adopt a limiting groove by way of example and not limitation, and the corresponding cross arm surface is provided with an annular bulge matched with the limiting groove, and the bulge can limit the horizontal movement of the cross arm after carrying out the limiting groove, so as to prevent the cross arm from separating from the open hole.

By way of example and not limitation, the steps of connecting the outer circulation pulling structure and the inner circulation pulling structure to form a closed loop by the connector structure will be described in detail below using the snap connection of the connector structure with the snap connection of the snap connector.

Specifically, the clamping structure comprises a female buckle and a male buckle which can be matched, the female buckle can adopt a groove, the inner wall of the groove is arc-shaped, and the corresponding male buckle adopts a circular protrusion; the sub-buckle can be inserted into the female buckle to form clamping connection under the action of external force, and the sub-buckle can be pulled out of the female buckle to release connection under the action of external force. When the child buckle is inserted into the female buckle for clamping, the child buckle can also rotate around the female buckle in an angle.

The joint structure comprises an upper joint piece and a lower joint piece, when the outer circulation traction structure and the inner circulation traction structure are connected, the upper end of the inner circulation traction structure is connected with the upper end of the outer circulation traction structure through the upper joint piece, and the lower end of the inner circulation traction structure is connected with the lower end of the outer circulation traction structure through the lower joint piece, so that a closed-loop cotton sliver transmission chain or transmission belt is formed, and the cotton sliver transmission chain or transmission belt is shown in fig. 5.

Specifically, the external circulation traction structure 180 may include a plurality of transmission chain units connected end to end, where the plurality of transmission chain units are also connected in the above-mentioned snap-fastener manner; wherein the end of the upper end of the transmission chain unit is set as a female buckle (corresponding to the upper end of the outer circulation traction structure 180 in fig. 5), and the end of the lower end of the transmission chain unit is set as a male buckle (corresponding to the lower end of the outer circulation traction structure 180 in fig. 5). Correspondingly, the internal circulation traction structure also comprises a plurality of transmission chain units connected end to end, and the plurality of transmission chain units are also connected by adopting snap fasteners; wherein the end of the lower last conveyor chain unit is configured as a box (corresponding to the joint structure of the lower end of the inner endless traction structure 194 in fig. 5) and the end of the upper last conveyor chain unit is configured as a sub-box (corresponding to the joint structure of the upper end of the inner endless traction structure 194 in fig. 5). That is, the upper box of the outer circulation traction structure 180 and the upper sub-box of the inner circulation traction structure 194 form an upper joint member, and the lower sub-box of the outer circulation traction structure 180 and the lower box of the inner circulation traction structure 194 form a lower joint member.

When the outer circulation traction structure and the inner circulation traction structure need to be connected, the controller controls the whole shifting robot 190 to move towards the position of the outer circulation traction structure 180, so that the inner circulation traction structure 194 enters between the two ends of the outer circulation traction structure 180, and at this time, the two ends of the inner circulation traction structure 194 and the two ends of the outer circulation traction structure 180 are located on the same straight line. Then, the controller controls the child buckle to move towards the child buckle direction (at this moment, a driving motor or a driving cylinder is arranged corresponding to the child buckle, the driving motor or the driving cylinder is connected with the controller and receives the control of the controller) or controls the parent buckle to move towards the child buckle direction (at this moment, a driving motor or a driving cylinder is arranged corresponding to the parent buckle, the driving motor or the driving cylinder is connected with the controller and receives the control of the controller), and the child buckle is inserted into the parent buckle to complete the clamping under the driving of the driving motor or the driving cylinder.

When the external circulation traction structure and the internal circulation traction structure are required to be separated, the controller controls the child buckle to move in a direction away from the parent buckle, or the controller controls the parent buckle to move in a direction away from the ion buckle (at the moment, the moving direction of the driving motor or the driving cylinder is opposite to the moving direction of the driving motor or the driving cylinder when the external circulation traction structure and the internal circulation traction structure are connected).

After the joint structure 195 connects the outer circulation pulling structure 180 and the inner circulation pulling structure 194, the outer circulation pulling structure 180 and the inner circulation pulling structure 194 form a closed loop tampon transfer chain or belt. By controlling the rotation of the driving wheel in the guide wheel, the driven wheel is driven to rotate, and the cotton sliver moves towards the feeding roller 132 under the action of the cotton sliver conveying chain or conveying belt.

The upper part of the internal circulation traction structure 194 is provided with a cotton sliver limiting structure 197, the cotton sliver limiting structure 197 is used for fixing the cotton sliver head 301 on the internal circulation traction structure 194, and when the internal circulation traction structure 194 moves towards the feeding roller 132, the cotton sliver limiting structure 197 and the cotton sliver head 301 are driven to move towards the feeding roller 132 together. When the sliver head 301 enters the front end of the sliver guide 131, the sliver limiting structure is released from fixing the sliver head 301, and the sliver is conveyed into the carding mechanism 120 under the rotation of the feeding roller 132.

In this embodiment, the sliver limiting structure is preferably a clamping structure. Specifically, an electric control clamping structure can be adopted, namely, the clamping and loosening of the clamp are controlled in an electric driving mode, and at the moment, the electric driving structure of the clamp is connected with the controller and receives the control of the controller; non-electric control clamping structures can also be adopted, namely, clamping and loosening of the clamp are controlled in a non-electric mode.

When the electric control clamping structure is adopted, preferably, the clamping structure comprises a clamp and a clamping canceling structure, and the clamping canceling structure can drive the clamp to loosen to cancel the clamping. And a position detection structure is also arranged corresponding to the clamp, the position information of the clamp is acquired through the position detection structure, whether the clamp reaches the front end of the bar guide is judged, and a clamping releasing instruction is sent out when the clamp reaches the front end of the bar guide.

And according to the clamping-releasing instruction, controlling the clamping-releasing structure to drive the clamp to release the fixing of the sliver head, and conveying the sliver to the carding mechanism under the rotation of the feeding roller.

Preferably, the position detecting structure may comprise a camera and an image recognition device, and the front end of the bar guide is provided with a detectable mark, such as a special surface color or special surface texture, or a detectable photoelectric element. The image data of the channel of the sliver guide is collected through the camera and sent to the image recognition device, when the sliver reaches the front end of the sliver guide, the detectable mark is covered, no detectable mark exists in the collected image data, the fact that the clamp reaches the front end of the sliver guide can be judged, and a clamping releasing instruction is sent out. According to the clamping-releasing instruction, the clamping-releasing structure drives the clamp to release, and the clamp is released from limiting (fixing) the sliver head.

When the clamping structure is in non-electric control, preferably, the clamping structure comprises a clamp movably arranged on the internal circulation traction structure, when the clamp reaches the front end of the sliver guide, the clamp is jacked up under the action of the feeding roller and/or the sliver guide to release the fixation of sliver heads, and the sliver is conveyed into the carding mechanism under the rotation of the feeding roller.

Preferably, the pushed-up clamp falls into a recovery groove arranged at the front end of the bar guide channel for recovery under the action of gravity after being separated from the internal circulation traction structure.

In another implementation manner of this embodiment, considering that light impurities with lighter weight such as flock are closer to the fiber conveying area, under the action of the fiber conveying negative pressure air flow, the light impurities are easy to accumulate in the stripping area and then are sucked back to the carding cavity to generate rolling back suction, and a impurity discharging structure combining free impurity falling and accurate impurity sucking is further provided.

Specifically, referring to fig. 6, a gettering port 171 is provided in the impurity removal surface 170 to perform gettering, corresponding to the impurity removal surface 170. In this embodiment, the impurity stripping surface is disposed at an angle of 60-70 deg. to the horizontal, preferably 65 deg..

During impurity removal, an impurity stripping channel inclined downwards is formed at the lower part of the carding roller through the impurity stripping surface. Under the combined actions of the air injection blast action of the air injection holes, the centrifugal force of the carding roller, the air supplementing supporting force and the gravity of the impurity stripping channel, the impurity stripping channel can comprise an effective fiber area, a rolling back suction area and a free impurity falling area from top to bottom. The long fibers of the effective fiber area remain in the carding chamber to participate in the yarn formation. The impurity in the reverse suction area is sucked into the impurity suction channel through the impurity suction port and discharged. Impurities in the free impurity falling region freely fall into the impurity discharging belt to be discharged.

Referring to fig. 7, for the uppermost effective fiber area 161a, the area has a long fiber length and a small weight per unit volume, and the carding air-supplementing holding force is greater than the combined force of the blowing force, the centrifugal force and the gravity, so that the limited fiber is kept in the carding cavity to participate in yarn formation. For the middle turnup reverse suction area 161b, the area mainly comprises light impurities, flock and other impurities (the impurities are easy to reversely suck back into the carding body due to the air-distributing and air-supplementing supporting force, the air-blowing force, the centrifugal force and the gravity leveling, so that unexpected broken ends are caused). Because the gettering is mainly used for removing light impurities, short velvet and the like, the reverse suction of the light impurities, short velvet and the like into the carding cavity is prevented, the requirement on the negative pressure of the gettering is low, and the low energy consumption is ensured. For the lower free-falling impurity area 161c, the area is mainly heavy impurities such as neps, cotton seed hulls, short thread heads and the like, the weight per unit volume is large, and the carding and air supplementing supporting force is far smaller than the comprehensive acting force of air injection blowing force, centrifugal force and gravity, so that the heavy impurities and the large impurities fall into the impurity discharging belt freely to be discharged. The scheme is particularly suitable for regenerated raw materials with more impurity content, heavy impurities, large impurities and the like in the impurities are discharged freely by combing centrifugal force, light impurities, short piles and the like in the impurities are removed by impurity absorption, transfer and removal, impurity rolling and back suction in an impurity discharging area of a combing cavity are eliminated, effective fiber yarn forming is reserved to the maximum extent, accurate impurity removal is realized, high yield is ensured, cotton knot breakage caused by impurity rolling and back suction is reduced, and spinning adaptability of the regenerated raw materials is improved.

In this embodiment, the impurity-sucking port, the impurity-sucking channel and the impurity-discharging area of the carding cavity may be separately manufactured and then spliced and assembled, or may be integrally formed. Preferably, the impurity sucking port, the impurity sucking channel and the impurity discharging area of the carding cavity are integrally formed. The front end of the gettering channel 172 is connected to the gettering port 171, or the gettering port 171 is formed as a part of the front end of the gettering channel 172.

With continued reference to fig. 7, the gettering channel 172 is preferably an L-shaped channel with rounded corners at the inside corners. The tail part of the impurity sucking channel 172 is communicated with the impurity sucking main air pipe through a suction pipe 173. The cross section of the suction pipe 173 is circular, the tail end of the suction pipe 173 is provided with a conical tail pipe with a gradually-reduced caliber, and the small-caliber end of the conical tail pipe is communicated with the impurity-sucking main air pipe.

Further, an air blowing device 174 may be provided corresponding to the suction port 171 or the suction passage 172. In one embodiment, the blowing device 174 can perform blowing cleaning on the impurity sucking port or the impurity sucking channel periodically, so as to prevent the impurity sucking pipeline from being blocked. In another embodiment, the blowing device 174 can also be used for blowing and cleaning the impurity sucking port or the impurity sucking channel according to the operation of a user, so as to prevent the impurity sucking pipeline from being blocked.

In the above description, the components may be selectively and operatively combined in any number within the scope of the present disclosure. In addition, terms like "comprising," "including," and "having" should be construed by default as inclusive or open-ended, rather than exclusive or closed-ended, unless expressly defined to the contrary. All technical, scientific, or other terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Common terms found in dictionaries should not be too idealized or too unrealistically interpreted in the context of the relevant technical document unless the present disclosure explicitly defines them as such.

Although the exemplary aspects of the present disclosure have been described for illustrative purposes, those skilled in the art will appreciate that the foregoing description is merely illustrative of preferred embodiments of the invention and is not intended to limit the scope of the invention in any way, including additional implementations in which functions may be performed out of the order of presentation or discussion. Any alterations and modifications of the present invention, which are made by those of ordinary skill in the art based on the above disclosure, are intended to be within the scope of the appended claims.

Claims (9)

1. An air suction auxiliary type spinning device combined with AI is used in a rotor spinning machine and comprises a cotton sliver feeding mechanism and a trash discharging carding mechanism, and is characterized in that:

the impurity removing and carding mechanism comprises a carding cavity provided with a carding roller, the carding cavity is communicated with the cotton sliver feeding mechanism and the fiber conveying channel, and an air supplementing channel and an impurity removing area of the carding cavity are arranged below the corresponding carding cavity; the surface of the carding roller is provided with a plurality of air suction holes in an array manner, the air suction holes are connected with an air suction device, and the air suction control device is connected with the air suction device and controls the air suction device;

the cotton sliver feeding mechanism comprises a sliver guide and a feeding roller, an outlet of a channel of the sliver guide is connected with the feeding roller, and cotton slivers are conveyed into the carding mechanism for carding under the rotation of the feeding roller; the sliver conveying mechanism is used for conveying sliver on the sliver can to the channel of the sliver guide device;

the device comprises a sliver guide channel, an air suction control device, an impurity detector, an air suction control device, a sliver guide channel and a sliver guide channel, wherein the impurity detector is arranged corresponding to the sliver guide channel and connected with the air suction control device, impurity information of the sliver in the sliver guide channel is detected through the impurity detector, a detection result is sent to the air suction control device, and the impurity information comprises area information of impurities;

The pumping control device is configured to: when cotton sliver fed into the carding cavity is carded by the carding roller, controlling the air suction holes on the carding roller corresponding to the area where the impurities are positioned according to the detection result to suck air to form negative pressure on the surface of the carding roller so as to generate auxiliary adsorption force, and sucking the impurities mixed in the cotton sliver through the air suction holes;

the sliver can conveying mechanism comprises a shifting robot with a base, a sliver can placing area and an internal circulation traction structure are arranged on the base, sliver can heads on sliver cans are fixed through sliver limiting structures arranged on the internal circulation traction structure, and the sliver limiting structures can be used for releasing the fixation of sliver can heads; the joint structure is arranged corresponding to the external circulation traction structure and/or the internal circulation traction structure, after the barrel is transported to the position of the external circulation traction structure through the shifting robot, the connector structure is controlled to connect the external circulation traction structure and the internal circulation traction structure to form a closed-loop cotton sliver conveying structure, and cotton slivers on the sliver cans are conveyed into a channel of the sliver guide through the cotton sliver conveying structure; and when the sliver head enters the front end of the sliver guide, the sliver limiting structure is released from fixing the sliver head, and the sliver is conveyed to the impurity removing carding mechanism under the rotation of the feeding roller.

2. The suction-assisted spinning apparatus according to claim 1, wherein: the carding roller comprises an inner cylinder fixedly arranged, an outer cylinder coaxially and rotatably arranged with the inner cylinder, and an adsorption cavity arranged between the outer cylinder and the inner cylinder;

the surface of the outer cylinder is provided with carding wires and air suction holes in an array manner, and impurities mixed in the inner side of the cotton sliver are sucked into the adsorption cavity through the air suction holes when air is pumped;

the inner cylinder is a hollow cavity, the hollow cavity is communicated with the air extractor, a vent hole is formed in the wall of the inner cylinder to communicate the adsorption cavity with the hollow cavity of the inner cylinder, and when air is extracted, air on the surface of the carding roller enters the adsorption cavity through the air suction hole and then enters the hollow cavity through the vent hole and is extracted by the air extractor.

3. The suction-assisted spinning apparatus according to claim 2, wherein: one end or two ends of the hollow cavity of the inner cylinder are communicated with an air extractor, and an adhesion layer is arranged in the adsorption cavity to adhere impurities entering the adsorption cavity.

4. The suction-assisted spinning apparatus according to claim 1, wherein: the sliver guide device comprises a feeding horn and a feeding plate, the feeding plate is positioned below the feeding roller, and the feeding roller and the feeding plate are commonly held to form holding force for sliver; the front end of the feeding plate forms a feeding jaw, a spring is arranged under the feeding plate, the pressure of the feeding jaw is from the spring, and the pressure of the feeding jaw is adjusted by adjusting the compression amount of the spring.

5. The suction-assisted spinning apparatus according to claim 4, wherein: the impurity detector comprises a camera, an image recognition unit and an impurity evaluation unit, wherein the camera is positioned at the inner side of the feeding horn; the camera is used for shooting image data of cotton sliver in the feeding horn and transmitting the image data to the image recognition unit, and the image recognition unit is used for carrying out recognition analysis on the image data of the cotton sliver to acquire impurity distribution information and impurity type information in the cotton sliver, and then sending the impurity distribution information and the impurity type information to the impurity evaluation unit; the impurity evaluation unit is used for evaluating the sliver impurity grade and marking an impurity key area according to the impurity distribution information and the impurity type information, and sending the evaluated sliver impurity grade and the marked impurity key area information to the air extraction control device;

the air suction control device can control the air suction holes of the corresponding areas on the carding roller to suck air according to the marked impurity key area information, and select the air suction quantity corresponding to the level according to the estimated sliver impurity level.

6. The suction-assisted spinning apparatus according to claim 1, wherein: the sliver detecting structure is arranged corresponding to the sliver guide, detects whether sliver exists in a preset area in a sliver guide channel through the sliver detecting structure, and sends a cylinder changing instruction when sliver does not exist;

According to the cylinder changing instruction, the joint structure is controlled to release the connection between the external circulation traction structure and the internal circulation traction structure, so that the cylinder conveying mechanism can be separated from the cotton sliver self-transmission mechanism, and the empty cylinder is conveyed away through the shifting robot.

7. The suction-assisted spinning apparatus according to claim 6, wherein: the cotton sliver limiting structure is a clamping structure, the clamping structure comprises a clamp and a clamping canceling structure, and the clamping canceling structure can drive the clamp to loosen to cancel clamping; a position detection structure is arranged corresponding to the clamp, position information of the clamp is obtained through the position detection structure, whether the clamp reaches the front end of the bar guide is judged, and a clamping releasing instruction is sent out when the clamp reaches the front end of the bar guide; and according to the clamping-releasing instruction, controlling the clamping-releasing structure to drive the clamp to release so as to release the fixation of the sliver head.

8. The suction-assisted spinning apparatus according to claim 1, wherein: the impurity stripping device comprises a carding roller, a carding cavity, a free-falling impurity zone, a impurity stripping surface, an impurity sucking channel and an impurity discharging zone, wherein the impurity stripping surface is arranged in a downward inclined mode, the impurity stripping surface is provided with an impurity sucking port, a downward inclined impurity stripping channel is formed at the lower part of the carding roller through the impurity stripping surface, the impurity stripping channel comprises an effective fiber zone, a turnover reverse sucking zone and the free-falling impurity zone from top to bottom, impurities in the turnover reverse sucking zone are sucked into the impurity sucking channel through the impurity sucking port to be discharged, and impurities in the free-falling impurity zone are freely fallen into the impurity discharging zone to be discharged.

9. The suction-assisted spinning apparatus according to claim 8, wherein: the impurity stripping surface and the horizontal surface are arranged obliquely downwards at an angle of 60-70 degrees.

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